Immediate Or Delayed Cord Clamping In The Preterm Birth Transition: Is There A Trade-off Between Circulatory Stability And Sympathoadrenal Activation?
Funder
National Health and Medical Research Council
Funding Amount
$824,582.00
Summary
Using an established experimental model of preterm birth, this project will determine if delayed clamping of the umbilical cord at birth leads to better stability of the circulation than immediate clamping, and if this improved stability comes at a cost of not activating the involuntary nervous system essential for enhancing metabolic and lung function after birth. The results of this study will provide fundamental new information for optimizing birth delivery strategies in preterm babies.
Novel Approaches To Assessing Cerebral Circulation And Oxygenation In Preterm Human Infants.
Funder
National Health and Medical Research Council
Funding Amount
$489,145.00
Summary
In the first few days after birth, some premature babies develop low blood pressure. It is thought that this meant that the amount of blood and oxygen going to the brain would also fall. If blood pressure became very low, this could injure the brain. Drugs are used to prevent low blood pressure, but their effect on blood flow and oxygen in the brain is uncertain. This study aims to develop simple cotside monitoring procedures that allow neonatologists to monitor oxygen supply and blood flow in t ....In the first few days after birth, some premature babies develop low blood pressure. It is thought that this meant that the amount of blood and oxygen going to the brain would also fall. If blood pressure became very low, this could injure the brain. Drugs are used to prevent low blood pressure, but their effect on blood flow and oxygen in the brain is uncertain. This study aims to develop simple cotside monitoring procedures that allow neonatologists to monitor oxygen supply and blood flow in the brain in tiny babies who weigh less than 1000gm, and what happens within the brain when drugs are given to raise blood pressure. We will employ a new instrument that generates low intensity near infrared light which passes safely into the brain and is absorbed according to the amount of oxygen present in very small blood vessels. As the methodology is new, we intend to first validate the measurement in immature lambs. The instrument will then be applied in studies of babies undergoing intensive care and at risk for low pressure and brain injury, as many as 5000 babies each year in Australia.Read moreRead less
INTRARETINAL OXYGEN CONSUMPTION AND THE PREVENTION OF HYPOXIA IN RETINAL ISCHEMIA
Funder
National Health and Medical Research Council
Funding Amount
$164,444.00
Summary
Adequate oxygen supply to the retina is critical for normal visual function. The oxygen is normally supplied by the blood flowing in the two circulations that support the retina. These are the choroidal circulation, lying behind the retina, and the retinal circulation, which supports the front half of the retina. The retinal circulation is particularly vulnerable to vascular disease and insufficient blood flow (ischemia). Vascular changes are involved in a wide range of retinal diseases which ar ....Adequate oxygen supply to the retina is critical for normal visual function. The oxygen is normally supplied by the blood flowing in the two circulations that support the retina. These are the choroidal circulation, lying behind the retina, and the retinal circulation, which supports the front half of the retina. The retinal circulation is particularly vulnerable to vascular disease and insufficient blood flow (ischemia). Vascular changes are involved in a wide range of retinal diseases which are currently responsible for the majority of new blindness in our community. The choroidal circulation is relatively robust, and offers a potential avenue for increasing oxygen delivery to the retina in the clinical management of ischemic retinal diseases. The feasibility of such an approach is strongly dependent on the oxygen requirements of the retina, and how this is influenced by retinal ischemia. We plan to find out how much oxygen is consumed by the many different layers within the retina under normal conditions and then determine how this changes under ischemic conditions. We will then see if we can supply enough oxygen from the choroid by a combination of raising the oxygen content of the blood, increasing choroidal blood flow, and reducing the amount of oxygen used by the outer half of the retina. Our experiments will be done in laboratory rats, but the same principles are readily transferable to humans if they prove to be beneficial in protecting the retina from ischemic damage. Our study will also quantify the relationship between oxygen levels in the blood stream, and those in the different layers of the retina. This information may prove valuable in the treatment and the prevention of other retinal diseases where the manipulation of the intraretinal oxygen environment is an exciting new avenue of research.Read moreRead less
A lack of oxygen in the kidney (hypoxia) is a primary cause of kidney disease, but the mechanisms are not clear. To determine the processes involved, we will take a new approach; combining a mathematical model with studies of kidney oxygen regulation in both normal and diseased kidneys. We will determine the causes of hypoxia in kidney disease, and find out if preventing hypoxia has the potential to be a treatment for kidney disease.
Domiciliary Oxygen Therapy In Interstitial Lung Disease
Funder
National Health and Medical Research Council
Funding Amount
$124,608.00
Summary
Interstitial lung diseases (ILD) are chronic lung diseases with significant health impacts, but limited drug treatment options. Although home oxygen treatment (HOT) is commonly used in these patients, its clinical benefits are uncertain with potential risks and significant costs for both patients and the health care system. Very little published information is available on the use of HOT in these patients. These studies aim to improve our knowledge and management of HOT in patients with ILD.